AT397885B - CONTROL DEVICE FOR THE OPERATION OF INDIVIDUAL ELEMENTS OF A HEATING SYSTEM - Google Patents

Description

AT 397 885 B

The present invention relates to a control device for operating a plurality of individual elements associated with a heating system, such as burners, mixers, circulation pumps, heat pumps and domestic water heaters, which are controlled by a central, digitally operating computer via lines, the elements being assigned plug-in modules.

It is already known to design a central control device with a large number of slots for individual modules, the modules being assigned to specific elements of the heating system, such as burners, mixers, heating curve settings and so on. Since a specific and reproducible connection between the modules and the central control unit is necessary, a specific module must also be regularly assigned to a specific slot. It follows that either a relatively large number of slots are available to satisfy the most varied needs of the selection of modules, which slots are generally never completely occupied, or that subsequent expansion or modification of the control device is impossible.

It is also known to provide a control device with purely digital data processing, the modules also being designed to operate digitally. However, this complete digitization has the disadvantage that a large number of digital pulses with a very large slope must be sent over the common data line, which leads to interference with other electrical devices, the interference from the data line likewise occurring.

Devices for controlling several consumers, in particular lighting fixtures or display segments, have become known from DE-OS 31 41 200 and DE-OS 33 05 579, in which the respective consumer is identified by means of an identifier. The identifier is implemented as a cyclic query using coded signals, digital pulse sequences generated by a microcomputer being used.

The present invention has set itself the task of achieving trouble-free operation of the individual modules on any slots.

The solution to the problem is that each plug-in module is assigned a known identifier with a defined voltage value, that all plug-in modules are connected via separate lines to an analog multiplexer, which in turn is connected to the computer via an AD converter, and that each plug-in module has its own analog multiplexer, each of which has a large number of inputs to which setting elements and / or switching elements can be connected. In this way, a simple assignment of the plug-in module to its respective intended purpose, i. H. to the corresponding element of the heating system. The data processing is carried out consistently in the analog process, so that interference with other electrical devices is excluded.

According to an advantageous development, the identifier is designed as a series connection of two resistors, which is connected to ground on the one hand and to a voltage source with a fictitious potential on the other, the connection point of the two resistors being connected via a line to an input of the analog multiplexer assigned to the plug-in module. Each plug-in module is equipped with a pair of resistors that have a very specific size, so that they can be easily distinguished from other plug-in modules.

Each plug-in module is preferably assigned actuators which are connected to the elements to which the plug-in module is assigned via plug-in lines. These actuators can be relays, for example, which control a burner, a mixer, a circulation pump or another individual element of the heating system assigned to the plug-in module.

Further refinements and particularly advantageous developments of the invention are the subject of the subclaims or emerge from the following description which explains an exemplary embodiment of the invention with reference to the figure of the drawing.

The figure shows a schematic representation of the entire control device with peripherals. A central control device 1 has a microcomputer 2 and an analog-digital converter 4 connected to it via a data bus 3. This data bus 3 serves for the transmission of address and information parts as well as control information.

The analog-digital converter is connected via a single line 5 to an analog multiplexer 6, from which a multiplicity of lines 7, 8, 9 .... to individual plug-in modules 10, 11, 12 .... originate. Each plug-in module is connected to the analog multiplexer 6 by a separate line, it being irrelevant how many lines or plug-in modules there are. The individual plug-in modules are assigned to certain elements of the heating system. For example, the plug-in module 10 is assigned to a mixing valve, the plug-in module 11 to a burner and the plug-in module 12 to a pump of the heating system. Further assignment options would be: a heat pump to make the heating system bivalent or the assignment of a cascade control to operate a multi-boiler system or one Assignment to a water heater. 2nd

AT 397 885 B

The microcomputer 2 is connected via a further data bus 13 to an output location 14, which in turn has three output lines 15. The number 3 depends on the maximum number of channels of the analog multiplexers 23 and could also be larger or smaller. Another 3-wire bundle 16 is present, which connects the output of the output location 14 to the analog multiplexer 6.

Each of the plug-in modules 10, 11, 12 ... is basically designed differently and adapted to the special purpose. (But there is also the possibility to design plug-in modules for different applications and to adapt them to the desired purpose only by using a different identifier)

The plug-in module 10, which is used to control a mixer, initially has a series connection of two resistors 17 and 18, which are connected to ground 19 on one side and to a voltage source 20 on the other side. A certain control voltage drops at the connection point 21 and is connected via a line 22 to a further analog multiplexer 23 assigned to each plug-in module. Through a suitable choice of the sizes of the two resistors 17 and 18, it is possible to assign a certain voltage potential to each plug-in module for the different applications. Each plug-in module is thus identified by assigning a discrete analog voltage value. This makes it possible to insert the plug-in module, whose voltage identification identifies it as a mixer module, into any slot in the control element 1. By querying the voltage value, the computer 2 can recognize that the mixer module is regularly assigned to the specific voltage value, regardless of a local arrangement.

Furthermore, the plug-in module 10 has a potentiometer 24 which is connected with its one pole to ground 19 and with its other pole to the voltage source 20. The grinder 25 is connected to the multiplexer 23 via a line 26. Depending on the position of the grinder 25, a specific voltage value can be attacked with the potentiometer 24, with which the hysteresis of the mixer position can be defined, for example. Furthermore, a button 27 is provided, which is connected on one side to ground 19 and on its other side at a branching point 28, which is connected on the one hand via a line 29 to the multiplexer and on the other hand via a resistor 30 to the pole of the voltage source 20. By closing the button 27, the pole 28 reaches a certain potential, namely ground. When the switch button 27 is open, on the other hand, the point lies at the potential of the voltage source 20. Thus, the multiplexers 23 can specify 2 discrete voltage potentials via the line 29, which in the application can mean, for example, which heating curve is currently being driven by the mixer or which temperatures in the on - and output lines of the mixer prevail. The buttons 27 can thus be used to selectively display certain sizes.

The structure of the other plug-in modules, which each have at least the identifier in common, is analogous. Here too, the identifier consists of a pair of resistors, the sizes of which, however, differ from those of resistors 17 and 18, so that each plug-in module carries on its line 22 a voltage value which differs from all others. Decisive for the formation of the mixer modules is the possibility of setting certain sizes and displaying certain sizes.

Furthermore, it is possible to assign actuators, for example relays, to the individual plug-in modules, in order to be able to forward steep commands to the elements assigned to the modules by means of lines (not shown) coming from the plug-in modules. For example, in the case of the plug-in module 10, it would make sense for the mixer to mount two relays on the plug-in module in order to cause a flap mixer to run clockwise or counterclockwise.

The line bundle 15 is connected to the multiplexer 23 via a 3-wire branch 31 and via further branches 31 to the respective other multiplexers 23 of the other plug-in modules 11, 12 and so on.

The function of the control device just described is as follows. The invention must be viewed on the premise that the control device 1 is used for any possible heating system that has not yet been established from the outset, with or without hot water preparation; to assign with or without heat pump, with or without underfloor heating to enable optimal operation, optimal not only in the direction of specified target temperatures, but also times. For example, it makes sense to charge a domestic hot water heater only at certain times, namely when it is likely that hot domestic water will be withdrawn shortly afterwards and to block the charging if no domestic water is expected to be needed for a long period of time. Furthermore, it makes sense to operate the heating system at a lower flow temperature at night than during the day; if necessary, lowering and ramp-up times can also occur during the day. Such a program will also look different for a married couple's house, where both users work, than for a house inhabited by a family with several children who are always present. 3rd

Claims (3)

AT 397 885 B If the control device is assigned to a heating system, you must first select the plug-in modules. Each device to be controlled in the heating system is provided with a plug-in module; for example, 5 plug-in module positions are provided in the control device from the outset. If the number of these plug-in module positions is not sufficient, the elements of the heating 5 system to be controlled must be weighted and the most important 5 positions selected. This will usually be the burner of the heating system, the water heater and the heating curve setting. The modules are labeled so that the user can see which element of the heating system they are assigned to, and they already have the voltage identifier described based on the different resistance values of the resistors 17 and 18. The plug-in modules are inserted into the slots in any manner, io whereby the cable bundle 31 and the lines 7, 8, 9, etc. are connected to one another by multiple plugs. The control device is thus operational when connected to the mains voltage. It should also be mentioned that the computer 2 has a clock and a display for this clock. If it is assumed that the entire heating system is in a cooled state, for example at the end of the night reduction period, this results, for example, in the computer at 6 a.m. a command to both 15 charge the domestic hot water heater and the heating system to a specific one based on the heating curve ramp up the specified flow temperature. For this purpose, the output location 14 is activated via the data bus 13, which sends out a control command via the line bundle 15, which queries whether a plug-in module is present which is assigned to the domestic hot water heater. For this purpose, all the multiplexers 23 are requested via these control commands to send their identification signal via the lines 7, 8, 9 and so on to the 20 ′ analog multiplexer 6. This means that all identifiers of all plug-in modules are on the entire bundle of lines 7, 8 and 9. Via the AD converter 4, the computer is able to find out the associated identification signal from the various identification signals, with which the computer has the information that a domestic hot water heater and its setpoint generator are present at all. Provided that the plug-in module 11 is assigned to the domestic water heater, its 25 identification signal remains on line 8, and the computer queries the associated target charging value via line bundle 15. At one of the input lines 32 of the analog multiplexer 23 of the plug-in module 11 there is a voltage value which, as an analog variable, corresponds to the temperature charging setpoint of the domestic hot water heater. This analog value is entered as a digital value into the computer 2 via the line 8 and the AD converter. In the event that the control relays 30 for the hot water heater are also on the plug-in module 11, a corresponding control command now goes back, and the hot water heater starts charging from the reduced value to the predetermined new setpoint. This applies in the event that the charge of the water heater has priority over the start-up of the heating. After the hot water temperature increase has ended, that is to say after the storage tank has been fully charged, the computer switches on the heating system as the second priority level, the plug-in modules 35 for the burner or the heating circulation pump being activated. The values stored there or the values set are read off and then either returned as control values directly via the plug-in module or the elements burner and circulation pump are controlled directly by computer 2. The most important of the present invention is the fact that each individual plug-in module used 40 has an identifier consisting of an analog voltage value, which represents the direct assignment of the module to the associated element of the heating system which is located elsewhere. It is also essential that exclusively analog data processing takes place within the individual plug-in modules and that the data paths are also transmitted from the plug-in modules to the analog multiplexer 6 at an analog value. A conversion into digital signals and then digitized data processing takes place only within the control device 1. 1. Control device for operating a plurality of elements associated with a heating system, such as burners, mixers, circulation pumps, heat pumps and water heaters, which are controlled by a central, digitally operating computer via lines, the elements being assigned plug-in modules, characterized in that Each plug-in module (10, 11, 12 ...) is assigned a known identifier with a defined voltage value, so that all plug-in modules (10, 11, 55 12 ...) via separate lines (7, 8, 9 ... ) are connected to an analog multiplexer (6), which in turn is connected to the computer (2) via an AD converter (4), and that each plug-in module (10, 11, 12 ...) has its own analog multiplexer (23), which each has a multiplicity of inputs (26, 29, 32) to which setting elements (25) and / or switching elements (27) can be connected 4 AT 397 885 B. 2. Control device according to claim 1, characterized in that the identifier is designed as a series connection of two resistors (17, 18) which is on the one hand to ground and on the other hand to a voltage source (20) with a fictitious potential, the connection point (21) of the two Resistors (17, 18) are connected via a line (22) to an input of the analog multiplexer (23) assigned to the plug-in module (10, 11, 12 ...). 3. Control device according to one of the preceding claims, characterized in that each plug-in module (10, 11, 12 ...) actuators are assigned which are connected via pluggable lines to the elements to which the plug-in module (10, 11, 12 .. .) assigned. With 1 sheet of drawings 5